Cross-linking of actin filaments by heavy meromyosin.

The structure of acto-heavy meromyosin has been examined by electron microscopy. When heavy meromyosin is mixed with actin at ~ 2 mg/ml a gel is formed. At lower actin concentrations more ordered assemblies are formed in which the actin filaments are in “rafts” about 300 Å apart cross-linked by heavy meromyosin. These results indicate that in solution the two heads of a heavy meromyosin molecule can bind to different actin filaments.     

Affinity chromatography of myosin, heavy meromyosin, and heavy meromyosin subfragment one on F-actin columns stabilized by phalloidin.

A method of affinity chromatography based on the trapping of actin filaments within agarose gel beads is described. This method can be used for the purification of myosin and its active proteolytic subfragments, as well as for studies on the interaction between actin and these proteins. Actin columns stabilized by phalloidin bind myosin, heavy meromyosin (HMM), and heavy meromyosin subfragment 1 (HMM-S1) specifically and reversibly. The effect of pyrophosphate and KCl on the dissociation of actomyosin, acto-HMM, or acto-HMM-S1 complex is reported. We also describe the single-step purification of myosin from a crude rabbit psoas muscle extract.     

Dynamic affinity chromatography of heavy meromyosin subfragment-1.

Heavy meromyosin subfragment-1 and its trinitrophenylated derivative have been chromatographed on immobilized ATP, ADP and adenosine 5'-(geta, gamma-imino) triphosphate affinity chromatography columns, in the presence and in the absence of Ng-2+ or Ca-2+.ma-32-P] ATP columns. While the divalent cations had little effect on the chromatographic pattern in the case of the non-hydrolyzable ADP and adenosine 5' (beta, gamma-imino) triphosphate, they catalyzed splitting in the case of ATP and at the same time strongly increased the affinity of adsorption of the proteins. The protein-elution and the Pi-release patterns were different for the native and the modified proteins. These results have been interpreted in terms of protein binding to the various intermediates of the ATP hydrolysis reaction.     

N-ethylmaleimide-modified heavy meromyosin. A probe for actomyosin interactions

Treatment of rabbit skeletal muscle heavy meromyosin (HMM) with the sulfhydryl reagent N-ethylmaleimide (NEM) produces a species of HMM which remains tightly bound to actin in the presence of MgATP. NEM-HMM forms characteristic "arrowhead" complexes with actin which persist despite rinses with MgATP. NEM-HMM inhibits the actin activation of native HMM-ATPase activity, the superprecipitation of actomyosin, the contraction of glycerinated muscle myofibrils, and the contraction of cytoplasmic strands of the soil amoeba Chaos carolinensis. However, NEM-HMM does not interfere with in vitro microtubule polymerization or beating of demembranated cilia.     

The substructure of heavy meromyosin. The effect of Ca2+ and Mg2+ on the tryptic fragmentation of heavy meromyosin.

Heavy meromyosin, obtained by tryptic digestion of myosin, containing two main polypeptides whose masses were estimated as 81,000 and 74,000 dlatons from Na dodecyl-SO4 polyacrylamide gel electrophoresis, was further digested with trypsin. The Ca2+-activated ATPase activity remainded unchanged and the K+-EDTA activity increased while various smaller fragments were formed. The formation of some of these fragments is affected by Ca2+ or Mg2+ as first shown by Bálint et al. (Bálint, M., Schaefer, A., Biro, N. A., Menczel, L., AND Fejes, E. (1971) J. Physiol. Chem. Phys. 3, 455). On the basis of the time course of the appearance of fragments the following relationship emerges: see article. The 64K leads to 60K step is inhibited by divalent cations, while the breakdown of the 74K fragment is accelerated. The effect of Ca2+ was maximal at 0 similar to 0.1 muM, that of Mg2+ at 10 muM. The original light chains of myosin are not present in the heavy meromyosin serving as the starting material, but peptide material appears on electrophoresis in positions starting material, but peptide material appears on electrophoresis in positions where the light chains would be found. The fragments marked by an asterisk are considered to ba alpha-helical on the basis of their solubility at low ionic strength after precipitation with ethanol (Bálint et al.). The fact that alpha helical fragments are derived from the 60,000-dalton fragment indicateds that it is adjacent to the light meromyosin in the intact myosin while the 74,000- dalton fragment would be part of heavy meromysoin subfragment 1. Chromatography of Sephadex G-200 separates fractions with ATPase activity corresponding to heavy meromyosin and heavy meromyosin subfragment 1. Electrophoresis of these Sephadex fractions suggests that the main peptide constituting heavy meromysoin subfragment 1 is connected by noncobalent forces to a portion of the rod that is not immediately adjacent to it in the primary sequence. The significance of this finding is discussed in terms of the flexibility of the myosin head.     

Interaction of anthracycline antibiotics with actin and heavy meromyosin.

For the purpose of elucidating the biochemical mechanism of anthracycline cardiomyopathy, the interaction with actin and heavy meromyosin (HMM) was studied. HMM and acto-HMM Mg²⁺-ATPase reactions were inhibited by daunorubicin and adriamycin; but not significantly by aclacinomycin A. The three antibiotics induced G-actin polymerization. Difference absorption spectra showed a direct interaction of adriamycin or aclacinomycin A with actin or HMM. Equilibrium dialysis and spectrofluorometric studies indicated that actin monomer possesses one binding site for adriamycin or aclacinomycin A with the same order of association constants (1.4 – 7.2 × 10⁴ M^?1). Adriamycin exhibited significantly higher affinity for HMM than aclacinomycin A.     

Interaction of actin with myosin A and heavy meromyosin.

Ca2+ "free" actomyosin suspensions as well as actin heavy meromyosin (HMM) solutions in the presence of Ca2+ showed no contractile response (superprecipitation) and had low steady-state Mg2+-ATPase activity. Under the same experimental conditions both the enzymatic activity increased and contractile response was restored if the solubility of the proteins was depressed by the addition of polyethylene glycol 4000 (PEG-4000). The stability of the enzymatically active actomyosin or actin HMM complexes was 10 times lower in cleared solutions than in the insoluble actomyosin or actin HMM suspensions. It was concluded that soluble actomyosin or actin HMM solutions are inadequate test tube models for studying muscular contraction.     

Transient electrical birefringence characterization of heavy meromyosin

Heavy meromyosin (HMM) and myosin subfragment 1 (S1) were prepared from myosin by using low concentrations of alpha-chymotrypsin. The light chain distribution in HMM was identical with that of myosin, within experimental error, when analyzed on 12% polyacrylamide gels after electrophoresis. Specific birefringences and birefringence decay times were measured by transient electrical birefringence in 5 mM KCl, 5 mM tris(hydroxymethyl)aminomethane (pH 7), and 1 mM MgCl2 at 4 degrees C under gentle conditions that reduced the CaATPase activity by less than 10%. For solutions of HMM, by use of electric field pulses shorter than 0.5 microseconds, the birefringence decay signal from the S1 portions of HMM could be resolved and the rotational motions of the S1 moieties observed directly. The rotation relaxation time, adjusted to 20 degrees C, was 0.34 microseconds; this is in quantitative agreement with previous hydrodynamic results obtained by using covalently attached probes. The assignment of the fast decay time obtained with HMM to the S1 portions was confirmed by birefringence decay measurements on free S1, for which the relaxation time was 0.13 microseconds, corrected to 20 degrees C. The specific birefringences for S1 and HMM, respectively, were 0.37 X 10(-6) and 12.8 X 10(-6) (cm/statvolt)2. Thus, for much longer electric field pulses, the signal from HMM is due almost entirely to its subfragment 2 (S2) portion, and its rotational dynamics can also be monitored directly by using electrical birefringence. The decay of the signal from the S2 portion could be adequately fit without evoking bending of the S2 portion of HMM other than at its junction with S1.     

Dielectric properties of polyelectrolytes. V. Dielectric dispersion of heavy meromyosin

Dielectric constant and dielectric loss of heavy meromyosin (HMM) were measured with varying pH. HMM showed a broader dispersion pattern than that with a single relaxation time especially on the high-frequencey side. The dielectric increment increased sharply with pH, above p^{H 6}, whereas the mean relaxation time and whole dispersion pattern were unchanged in the same region. The values of the increment and the mean relaxation time were much larger than those of usual globular proteins. The dispersion profile, pH dependence, and values of the increment are well explained by Oosawa's counterion fluctuation theory. Other mechanisms are more or less inadequate to our results. In the low pH region below the isoelectric precipitation region, both the increment and the mean relaxation time decreased; this is probably due to partial denaturation and suppression of the dissociation of carboxyl groups. An experiment on a urea-denatured sample supports this assumption. The biological significance of the pH dependence is discussed.     

The tryptic digestion of spin-labelled heavy meromyosin

The S₁ thiol groups of heavy meromyosin (HMM) have been selectively spin labeled with a paramagnetic analog of iodoacetamide (10) and the effects of tryptic digestion on the ESR spectrum and ATPase activity have been studied. The loss of ATPase activity on tryptic digestion occurs at the same rate with spin-labeled or unlabeled HMM suggesting that spin labeling produces no major change in the conformation of HMM. ESR spectra indicate that spin labels bound to S₁ groups of HMM are strongly immobilized; spectra of subfragment-1 isolated from tryptic digests of spin-labeled HMM are the same as those of labeled HMM. ESR spectra of S₁-spin-labeled peptides produced by tryptic digestion of HMM indicate essentially no immobilization of labels, the spectra being similar to that of a solution of free labels. The ESR spectrum of an unfractionated digest of HMM exhibits a peak attributable to strongly immobilized labels on HMM and subfragment-1 and a peak attributable to weakly immobilized labels bound to peptides. The rate at which spin-labeled peptides are released on tryptic digestion can be measured on the unfractionated digest by the decrease in the ESR peak corresponding to HMM and subfragment-1. The appearance of peptides containing spin-labeled S₁ groups parallels the loss of ATPase activity. No evidence has been found for the existence of an enzymatically active subfragment-1 lacking S₁ thiol groups.     

Calcium-dependent structural changes in scallop heavy meromyosin

The mechanism of calcium regulation of scallop myosin is not understood, although it is known that both myosin heads are required. We have explored possible interactions between the heads of heavy meromyosin (HMM) in the presence and absence of calcium and nucleotides by sedimentation and electron microscope studies. The ATPase activity of the HMM preparation was activated over tenfold by calcium, indicating that the preparation contained mostly regulated molecules. In the presence of ADP or ATP analogs, calcium increased the asymmetry of the HMM molecule as judged by its slower sedimentation velocity compared with that in EGTA. In the absence of nucleotide the asymmetry was high even in EGTA. The shift in sedimentation occurred with a sharp midpoint at a calcium level of about 0.5 microM. Sedimentation of subfragment 1 was not dependent on calcium or on nucleotides. Modeling accounted for the observed sedimentation behavior by assuming that both HMM heads bent toward the tail in the absence of calcium, while in its presence the heads had random positions. The sedimentation pattern showed a single peak at all calcium concentrations, indicating equilibration between the two forms with a t(1/2) less than 70 seconds. Electron micrographs of crosslinked, rotary shadowed specimens indicated that 81 % of HMM molecules in the presence of nucleotide had both heads pointing back towards the tail in the absence of calcium, as compared with 41 % in its presence. This is consistent with the sedimentation data. We conclude that in the "off" state, scallop myosin heads interact with each other, forming a rigid structure with low ATPase activity. When molecules are switched "on" by binding of calcium, communication between the heads is lost, allowing them to flex randomly about the junction with the tail; this could facilitate their interaction with actin in contracting muscle.     

The interaction of C-protein with heavy meromyosin and subfragment-2.

C-protein has previously been shown to bind to the light-meromyosin region of the myosin tail. Examination of mixtures of C-protein with heavy meromyosin or subfragment-2 or subfragment-1 in the analytical ultracentrifuge shows that there is also a binding site for C-protein in the subfragment-2 region of the tail.